Modelling the effect of density vegetation coverage and the occurrence of peridomestic infestation by <i>Triatoma infestans</i> in rural houses of northwest of Córdoba, Argentina

CARDOZO, MIRIAM; ESTALLO, ELIZABET L.; SORIA, CAROLA; RODRÍGUEZ, CLAUDIA S.; LÓPEZ, ANA G.; NATTERO, JULIETA; CROCCO, LILIANA B.

doi:10.1590/0001-3765202120191178

Abstract

To better understand the dispersion strategies of Triatoma infestans (Klug) (Hemiptera: Reduviidae, Triatominae), we evaluated the spatial effect of infested peridomicile and density vegetation cover in a historically endemic area for Chagas disease. The study was conducted in rural houses of the northwest of Córdoba province, Argentine, during 2012-2013. Active search of triatomines were made in domicile and peridomicile habitats. To characterize vegetation coverage, a thematic map was obtained considering five types of vegetation cover (closed/open forest, closed/open shrubland and cultural land). From each house we extracted the area of vegetation coverage, housing density and infested peridomiciles density. We used generalized linear models to evaluate the effect of these variables on the occurrence of infested peridomicile. According to our results, the probability of a peridomicile to be infested increases by 1.34 (95%CI [0.98; 1.90]) times more when peridomicile structures are in environments with higher housing density and by 1.25 (95%CI [0.84; 1.88]) more times when houses are surrounded by open shrublands. Among the multiple ecological determinants of peridomestic infestation, the influence of vegetation cover has been poorly studied. In this study we discussed the effect of the vegetation as a potential modulator of the dispersion strategies of T. infestans.

Key words
Dispersion; infestation; peridomicile; Triatoma infestans; vegetation

INTRODUCTION

Chagas is one of the most important endemic diseases in Latin America. It is caused by the protozoan Trypanosoma cruzi, which is transmitted to humans and other mammals mainly via blood-sucking insects from the Reduviidae family, Triatominae subfamily (OMS 2007OMS - ORGANIZACIÓN MUNDIAL DE LA SALUD. 2007. Reporte sobre la Enfermedad de Chagas. Reporte del grupo de trabajo científico sobre la enfermedad de Chagas. Buenos Aires, Argentina.).

In South America, Triatoma infestans is the vector of greatest epidemiological importance, characterized by its high adaptive capacity to human dwellings (Rabinovich 1972RABINOVICH JE. 1972. Vital statistics of Triatominae (Hemiptera: Reduviidae) under laboratory conditions. I. Triatoma infestans Klug. J Med Entomol 9: 351-370., Lent & Wygodzinsky 1979LENT H & WYGODZINSKY P. 1979. Revision of the Triatominae (Hemiptera, Reduviidae), and their significance as vectors of Chagas disease. Bull Am Mus Nat Hist 163: 123-520.). They are found almost exclusively in domestic environments and peridomestic habitats such as chicken coops, goat pens, pig corrals and storerooms, which show optimum conditions for the establishment of colonies (OMS 2007OMS - ORGANIZACIÓN MUNDIAL DE LA SALUD. 2007. Reporte sobre la Enfermedad de Chagas. Reporte del grupo de trabajo científico sobre la enfermedad de Chagas. Buenos Aires, Argentina.).

The Southern Cone Initiative to Control Chagas Disease (INCOSUR), launched in 1991, succeeded in reducing the distribution area of T. infestans to less than 1 million km² through insecticide-based vector control, health education and house improvement program (Schofield et al. 2006SCHOFIELD CJ, JANNIN J & SALVATELLA R. 2006. The future of Chagas disease control. Trends Parasitol 12: 583-588.). The interruption of vector transmission of T. cruzi was achieved in Uruguay (2012), Chile (1999), two Departments of Bolivia (2011 – 2013), eastern region of Paraguay (2008) and Alto Paraguay (2013) as well as in eight provinces of Argentina between 2001 and 2013 (PAHO 2012PAHO - PAN AMERICAN HEALTH ORGANIZATION. 2012. XIV Reunión de la Comisión Intergubernamental de la Iniciativa de los Países de Centroamérica (IPCA) para la Interrupción de la Transmisión Vectorial, Transfusional y Atención Médica de la Enfermedad de Chagas; Ciudad de Belice, Belice. Available from: https://www.paho.org/hq/dmdocuments/2012/2012-XIV-IPCA-Reunion.pdf).

Nevertheless, in arid Gran Chaco areas of Argentina, Paraguay and Bolivia, reinfestations of human dwellings continue to occur in several provinces or departments (Gürtler 2009GÜRTLER RE. 2009. Sustainability of vector control strategies in the Gran Chaco Region: current challenges and possible approaches. Mem Inst Oswaldo Cruz 04: 52-59.). Many authors agree that the persistence of triatomine infestation in the Chaco region is due to the difficulty of eliminating the vector population in peridomestic habitats (Cecere et al. 1997CECERE ME, GURTLER RE, CANALE D & COHEN JE. 1997. El papel del peridomicilio en la eliminación de Triatoma infestans de las comunidades rurales argentinas. Bull Pan Am Health Organ 121: 1-10.). After the residual application of pyrethroid insecticides, chicken coops, goat pens, pig corrals and other potential habitat in the peridomicile are the first to be recolonized (Canale et al. 2000CANALE DM, CECERE MC, CHUIT R & GÜRTLER RE. 2000. Peridomestic distribution of Triatoma garciabesi and Triatoma guasayana in north-west Argentina. Med Vet Entomol 14: 383-390.), because their complex structure not only prevent good penetration of insecticides (Gürtler 2009GÜRTLER RE. 2009. Sustainability of vector control strategies in the Gran Chaco Region: current challenges and possible approaches. Mem Inst Oswaldo Cruz 04: 52-59.) but also provide optimal conditions for sustaining near domiciles abundant triatomines population (Cecere et al. 2006CECERE MC, VAZQUEZ-PROKOPEC GM, GÜRTLER RE & KITRON U. 2006. Reinfestation sources for Chagas disease vector, Triatoma infestans, Argentina. Emerg Infect Dis J 12: 1096-1102.). Hence, the active dispersal of T. infestans (flying and walking) plays an important role in the local propagation of triatomines within and between neighboring households (Vazquez-Prokopec et al. 2004VAZQUEZ-PROKOPEC GM, CEBALLOS LA, KITRON U & GÜRTLER RE. 2004. Active Dispersal of Natural Populations of Triatoma infestans (Hemiptera: Reduviidae) in Rural Northwestern Argentina. J of Med Ent 41(4): 614-621., Abrahan et al. 2011ABRAHAN L, GORLA DE & CATALÁ SS. 2011. Dispersal of Triatoma infestans and other Triatominae species in the arid Chaco of Argentina - Flying, walking or passive carriage? The importance of walking females. Mem Inst Oswaldo Cruz 106: 232-239.).

Several studies conducted in semiarid regions of Argentina determine that at local scales, the spatial patterns of reinfestation of peridomicile and domicile habitats are determined by flight dispersal capacity, local abundance of triatomines and hosts, the spatial configuration of households and vegetation cover (Vazquez-Prokopec et al. 2004VAZQUEZ-PROKOPEC GM, CEBALLOS LA, KITRON U & GÜRTLER RE. 2004. Active Dispersal of Natural Populations of Triatoma infestans (Hemiptera: Reduviidae) in Rural Northwestern Argentina. J of Med Ent 41(4): 614-621., McGwire et al. 2006MCGWIRE K, SEGURA E, SCAVUZZO M, GÓMEZ AA & LAMFRI M. 2006. Spatial pattern of reinfestation by Triatoma infestans in Chancaní, Argentina. J Vector Ecol 31: 17-28., Abrahan et al. 2011ABRAHAN L, GORLA DE & CATALÁ SS. 2011. Dispersal of Triatoma infestans and other Triatominae species in the arid Chaco of Argentina - Flying, walking or passive carriage? The importance of walking females. Mem Inst Oswaldo Cruz 106: 232-239.). However, little is known about how vegetation cover surrounding houses affect the spatial distribution of infestations. Some authors mentioned that dense vegetation cover and high trees may act as a barrier for triatomine dispersal (Vazquez Prokopec et al. 2004).

The northwest region of Córdoba Province, located in the south of the Gran Chaco region of Argentina, shows a heterogeneous scenario of T. cruzi transmission related with differences in vector control interventions, land use changes and socioeconomic factors in the last decades (Moreno et al. 2010MORENO M, MORETTI E, BASSO B, FRIAS M, CATALÁ S & GORLA D. 2010. Seroprevalence of Trypanosoma cruzi infection and vector control activities in rural communities of the southern Gran Chaco (Argentina). Acta Trop 113: 257-262., 2012MORENO ML, HOYOS L, CABIDO M, CATALÁ SS & GORLA DE. 2012. Exploring the association between Trypanosoma cruzi infection in rural communities and environmental changes in the southern Gran Chaco. Mem Inst Oswaldo Cruz 107: 231-237.). Previous reports on the area (Crocco et al. 2019CROCCO L, NATTERO J, LÓPEZ A, CARDOZO M, SORIA C, ORTIZ V & RODRIGUEZ C. 2019. Factors associated with the presence of triatomines in rural areas of south Argentine Chaco. Rev Soc Bras Med Trop 52: e-20180357.), showed a high peridomiciliar infestation, strongly associated with the presence of chicken coops. This peridomestic habitat is the most frequent in the area and the most vulnerable to infestation because the materials of construction (sticks, wood, or cardboard) provide excellent refuge sites for triatomines. Soria et al. (2019)SORIA C, CARDOZO M, CANAVOSO LE, CROCCO LB, NATTERO J, ORTIZ VAP, LEYRIA J & RODRIGUEZ CS. 2019. Host influence on the nutritional and reproductive status of Triatoma infestans (Klug) (Hemiptera: Reduviidae) peridomiciliary populations. Rev Soc Entomol Arg 78(2): 1-11. report within the same area a high percentage of combined blood meals (goat, chicken, dog and human) on feeding profiles of T. infestans collected in peridomicile. This record does not seem to be related to host-feeding source choice nor to the main host residing in the peridomicile, since most of the triatomines that recorded mixed blood ingestion were found in peridomiciles with only one type of host present. Hence, this study evidence a high dispersion of adult T. infestans between peridomiciles in natural conditions, which reinforces the importance of better understanding how environmental and spatial factors may modulate the dispersal strategy of triatomines.

The aim of our study was to evaluate the spatial effect of peridomestic infestation and density vegetation cover in a historically endemic area for Chagas disease, in order to add understanding on the dynamics of dispersion of T. infestans. We hypothesize that the density of the vegetation cover influences the dispersion of triatomines between nearby peridomicile by facilitating or preventing the transmission of physical and chemical signals from the peridomiciliary area. Infrared radiation, thermal signals emitted by domestic hosts as well as the mixture of odor cues and lights can be perceived in a range of meters by T. infestans, and may influence the appetitive searching and long-range orientation (Guerensten & Lazzari 2009GUERENSTEN P & LAZZARI C. 2009. How triatomines acquire and make use of information to find blood. Acta Trop 110: 148-158., Catalá 2011CATALÁ SS. 2011. The infra-red (IR) landscape of Triatoma infestans. A hypothesis about the role of IR radiation as a cue for Triatominae dispersal. Infect Genet Evol 11: 1891-1898.).

MATERIALS AND METHODS

Study area

The field work was conducted in six rural communities of Cruz del Eje and Ischilín departments, at northwest Cordoba province, Argentina, between latitudes -30° and -31° S and longitudes -64° and -65° O (Figure 1a-b). This region belongs to the Chaco phytogeographical province (Cabrera 1976CABRERA AL. 1976. Regiones Fitogeográficas Argentinas. Enciclopedia Argentina de Agricultura y Jardinería, 2ª Edición, Tomo II, Fascículo I, Acme S.A.C.I., Buenos Aires: Argentina, p. 132-134.), characterized by a subtropical dry climate with a summer season from October to March. The average monthly temperature is 26 °C, with absolute maximum temperatures that exceed 45 °C (Karlin et al. 2013KARLIN MS, KARLIN UO, COIRINI R O, REATI GJ & ZAPATA RM. 2013. El Chaco Árido. Ed. Encuentro, p. 15-23.).

Figure 1
a) Location of the study area in the extreme south of the Gran Chaco region (shaded area). b) Location of rural houses evaluated in the six communities of Cruz del Eje and Ischilín departments, Córdoba province, Argentina.

Entomological data

The study was carried out in sixty-six rural houses that were visited between December 2012 - November 2013 and were georeferenced in the field using GPS (Garmin Etrex 20). The communities and the houses visited were selected according to the recommendations of the National and Provincial Program of Chagas. The last insecticide spraying campaign by vector control personnel was carried out in these communities three years before this study.

The man-hour technique was carried out in domicile and peridomicile -chicken coops, goat and pig corrals- for the active search of triatomines (Chuit et al. 1992CHUIT R, PAULONE I, WISNIVESKY-COLLI CBR, PEREZ AC, SOSA-STANI S & SEGURA EL. 1992. Result of a first step toward community-based surveillance of transmission of Chagas disease with appropriate technology in rural areas. Am J Trop Med Hyg J 46: 444-450.). The captured triatomines were identified taxonomically according to the identification keys of Lent & Wygodzinsky (1979)LENT H & WYGODZINSKY P. 1979. Revision of the Triatominae (Hemiptera, Reduviidae), and their significance as vectors of Chagas disease. Bull Am Mus Nat Hist 163: 123-520. and Brewer et al. (1983)BREWER M, GORLA D & GARAY ME. 1983. Caracterización de los estadios ninfales del género Triatoma Laporte, 1833. III Análisis biométrico descriptivo de Triatoma infestans Klug, 1834; Triatoma platensis Neiva, 1913; Triatoma delpontei Romaña y Avalos, 1947 y Triatoma sordida (Stal) 1859 (Hemiptera: Reduviidae). Rev Soc Entomol Arg 42: 219-241..

Estimation of vegetation cover and spatial variables

To identify the landscape coverage classes, it was used a Landsat 8 image generated by the OLI sensor, corresponding to scene 230-81, with an acquisition date of May 8, 2013, provided by the US Geological Survey (USGS) (http://earthexplorer.usgs.gov/). The vegetation cover was characterized by obtaining a thematic map by supervised classification (maximum likelihood method) of the image. Subsequently, five types of coverage were defined: closed forest, open forest, open shrubland, closed shrubland and cultural land (comprising agricultural lands and small towns). Coverage classes were defined based on training sites that were registered in the field and considering the units defined by Cabido & Zak (1999)CABIDO MR & ZAK MR. 1999. Vegetación del Norte de Córdoba Cabido. Secretaría de Agricultura, Ganadería y Recursos Renovables de Córdoba, p. 55-56. and Hoyos et al. (2013)HOYOS LE, CINGOLANI AM, ZAK MR, VAIERETTI MV, GORLA DE & CABIDO MR. 2013. Deforestation and precipitation patterns in the arid Chaco forests of central Argentina. Appl Veg Sci 16: 230-271.. To check the accuracy of the classification obtained, the confusion matrix method was used. The ENVI 5.1 software (Environment for Visualizing Images, Research Systems, 2013) was used for the pre-processing and processing of the images.

On the thematic map, a circular area with a radius of 200 meters was generated around each house, from which the class area (Ha.) of each kind of coverage was extracted. The Fragstat 4.2 software (McGarigal et al. 2012MCGARIGAL K, CUSHMAN SA & ENE E. 2012. FRAGSTATS v4: Spatial Pattern Analysis Program for Categorical and Continuous Maps. Computer software program produced by the authors at the University of Massachusetts, Amherst. Available at the following web site: http://www.umass.edu/landeco/research/fragstats/fragstats.html) was used for extracting the class metrics.

For each rural house, additional variables were calculated in order to characterize the spatial dependence of infested peridomiciles: housing density (HD) in an area of 200 m radius (number of houses / Ha.) and infested peridomiciles density (IPD) in an area of 200 m radius (number of infested peridomiciles / Ha.).

Statistical analysis

Spatial heterogeneity of infested peridomiciles between rural communities was measured using SaTScan software v9.6 (Kulldorff 1997KULLDORFF MA. 1997. A spatial scan statistic. Theory Method 26: 1481-1496.). We use spatial analyses with a Poisson model to detect clusters of significant high and low infestation within a maximum circular size equal to 50% of the entire area.

To evaluate the effect of spatial dependence variables (HD and IPD) and vegetation cover variables on the occurrence of infested peridomiciles (binary variable) we used generalized linear models (GLM) with binomial error distribution, and logit link function. In order to avoid collinearity, correlation analyses among explanatory variables were performed to make a selection.

We hypothesized that rural peridomiciles spatially located in environments with high density of housing and higher density of positive peridomiciles around will be more likely to be infested. In addition, since density vegetation cover was mentioned as a possible modulator of dispersion, it would be expected that houses surrounded by less dense vegetation cover (like open shrublands) will have more chances of peridomicile infestation than others surrounded by dense and higher vegetation.

The set of candidate models considered the individual effects of each predictor on the response variable as well as joint models evaluating the additive effects of the possible combinations. The best model was selected following Akaike’s information criterion (AICc), using the function aictab of the package AICmodavg in the R software version 3.4.3. Multicollinearity between the variables included in each developed model were also tested with the variance inflation factor (VIF) (Zuur et al. 2007ZUUR AK, IENO EN & SMITH GM. 2007. Data exploration. Analysing Ecological Data. Springer: United States of America, p. 633-648.). The effect-size estimates for each variable was averaged, using the modavg function from the package AICmodavg in the R software version 3.4.3, for all coefficients included in models that showed a difference in AIC values ≤ 2 with the model that showed the lowest AIC. The odd ratios for the binomial GLM were calculated for each predictor using the exponential transformation of the estimated coefficient (Zuur et al. 2009ZUUR AK, IENO EN, WALKER NJ, SAVELIEV AA & SMITH GM. 2009. Mixed Effects Models and Extensions in Ecology with R. Springer: United States of America, p. 246-250.). Finally, the relative importance of the explanatory variables was determined by summing the weights/probabilities (aiccwt) of the models in which each predictor appears (Calcagno 2013CALCAGNO V. 2013. Glmulti: Model Selection and Multimodel Inference Made Easy. 1.0.7 edn2013: R package. https://cran.r-project.org/web/packages/glmulti/glmulti.pdf
https://cran.r-project.org/web/packages/... ).

RESULTS

Entomological data

From the total of houses visited during the study, 43.9 % (29) were infested only in peridomestic habitats and 1.5 % (1) was infested in both ecotopes (domestic and peridomestic habitats). A total number of 633 triatomines were collected during the active search, including 451 nymphs and 182 adults of T. infestans recorded in peridomestic habitat mostly in chicken coops and less frequently in goat pens. Table I report the values obtained.

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Table I
Entomological data collected during 2012-2013 on rural communities in Northwest of Córdoba province, Argentina.

Estimation of vegetation cover and spatial variables

The thematic map obtained from Landsat 8 image with supervised classification is displayed in Figure 2a-b. The classification of the satellite image to obtain the thematic map had an accuracy of 93 % and a kappa value of 0.92, according to the confusion matrix.

Figure 2
a) Thematic map of estimated vegetation covers in the study area. References on the map. b) Detail of the circular area of influence with a radius of 200 m from which the class area of each kind of coverage and spatial variables were calculated. The detailed area corresponds to the area indicated by the arrow in figure 2.a.

Of the five classes of vegetation cover defined in the study area, four were represented in the closest surroundings of the houses: open forest, closed shrubland, open shrubland and cultural land. The latter shows a strong negative correlation with the area of open shrubland (r = -0.80) and closed shrubland (r = -0.77). So, the cultural land effect on the response variable was evaluated in a single model, but it was not considered in the construction of the joint models, since the analysis focused on the vegetation cover classes as a possible dispersion modulator in order to contrast the hypotheses proposed.

Spatial analysis and multi-model inference

The spatial analysis of infested peridomicile resulted in three non-significative clusters showing that the infestation was homogeneously distributed between rural communities in the study area.

To analyze the predictors of infested peridomicile occurrence, we built fourteen candidate models (Table II) considering the individual effects of each predictor on the response variable as well as joint models evaluating the possible combination between variables in agreement with the alternative hypothesis. From the fourteen candidate models of the multimodel inference approach, four of them described equally well the results (ΔAICc ≤ 2.0). These four-best fitting GLMs included the housing density in combination with infested peridomicile density and open shrubland area as predictors. The most parsimonious model for explaining the occurrence of infested peridomicile was the one that included only the housing density as an explanatory variable (AICc = 91.17). However, the model including housing density and open shrubland area also had good explanatory power with a slightly higher AICc (92.12).

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Table II
Model set. Results of the multi-model inference analysis of all GLMs considered in this study to explain the occurrence of peridomestic infestation (Y) in rural houses of the northwest of Córdoba province, Argentina.

No multicollinearity was found between the explanatory variables in the four-best fitted GLMs (VIF<1.81).

In line with the alternative hypothesis, the model-averaged estimate reveals that housing density and open shrubland have a positive effect on peridomestic infestation with an estimated log-odd value of 0.35 (95%CI [-0.04; 0.75]) and 0.22 (95%CI [-0.17; 0.62]) respectively. Whereas the infested peridomicile density estimated log-odd value shows a negative effect on the response variable (-3.53; 95%CI [-9.99; 2.93]) though with a high unconditional standard error (SE= 3.29) and a wide confidence interval. The estimated odd ratios for housing density were 1.34 (95%CI [0.98; 1.90]) and for open shrubland and infested peridomicile density were 1.25 (95%CI [0.84; 1.88]) and 0.02 (95%CI [0.00; 16.68]) respectively.

Finally, the AIC weights of the models (Table II) revealed that the housing density had the higher relative importance supporting the models followed by the open shrubland area.

DISCUSSION

Entomological data recorded in this study shows high peridomestic infestation (43.9 %) and very low domestic infestation (1.5 %) by T. infestans in rural houses of the northwest of Córdoba Province during 2012-2013. Previous reports published within the same area, pointed out that low domestic infestation was related with the improvement of housing construction and that the risk of peridomestic infestation was strongly associated with the presence of chicken coops (Crocco et al. 2019CROCCO L, NATTERO J, LÓPEZ A, CARDOZO M, SORIA C, ORTIZ V & RODRIGUEZ C. 2019. Factors associated with the presence of triatomines in rural areas of south Argentine Chaco. Rev Soc Bras Med Trop 52: e-20180357.). Since rural houses were visited after a three year-period without chemical control, the levels of peridomestic infestation recorded supports the fact that without a sustainable control campaign the populations of T. infestans remain far from the elimination objectives proposed by the Southern Cone Initiative (Segura 2002SEGURA EL. 2002. Historia del control de la enfermedad de Chagas en Argentina. En: O controle da doenca de Chagas nos países do Cone Sul da América. História de uma Iniciativa Inernacional, p. 42-109.).

The results obtained in this study show that the probability of a peridomicile to be infested by T. infestans in the study area increased by 1.34 times more when peridomicile structures are in environments with higher housing density. The effect of housing density as a predictor of infestation status for peridomestic structures as well as domicile had already been observed by McGwire et al. (2006)MCGWIRE K, SEGURA E, SCAVUZZO M, GÓMEZ AA & LAMFRI M. 2006. Spatial pattern of reinfestation by Triatoma infestans in Chancaní, Argentina. J Vector Ecol 31: 17-28. in similar rural areas of northwest of Córdoba province. Given that local livestock economy in the area is based on smaller-scale poultry and goat production, a higher density of housing is related to a higher density of chicken coops and goat pens. This means greater chances of triatomine dispersion among ecotopes in search of food, as it was recorded in the same area by Soria et al. (2019)SORIA C, CARDOZO M, CANAVOSO LE, CROCCO LB, NATTERO J, ORTIZ VAP, LEYRIA J & RODRIGUEZ CS. 2019. Host influence on the nutritional and reproductive status of Triatoma infestans (Klug) (Hemiptera: Reduviidae) peridomiciliary populations. Rev Soc Entomol Arg 78(2): 1-11..

Although the infested peridomicile density variable has an unexpected negative effect on the probability of a peridomicile to be infested, this may be due to the fact that the number of rural houses visited around each positive house for T. infestans was not always constant because some inhabitants were absent or were reluctant to participate, preventing us to do the search of triatomines.

Based on the models carried out in this study, it can be observed that the probability of a peridomicile to be infested also increases by 1.25 more times when houses are surrounded by open shrubland. In general, studies that consider vegetation as a variable related to the presence of T. infestans, evaluate its indirect effect on temperature and precipitation using temporal series of NDVI (Gorla 2002GORLA DE. 2002. Variables ambientales registradas por sensores remotos como indicadores de la distribución geográfica de Triatoma infestans (Heteroptera: Reduviidae). Ecol Austral 12: 117-127.) or landscape metrics to reflect the livestock productivity in the area (Porcasi et al. 2011PORCASI X, GORLA DE & SCAVUZZO MC. 2011. A landscape ecology approach for a neglected disease in rural areas of Argentina. Acta Biol Venez 31: 27-32.). However, little it has been mentioned of the possible effect of local vegetation around the house as a potential modulator of dispersion of triatomines between neighboring ecotopes. According to Vazquez-Prokopec et al. (2004)VAZQUEZ-PROKOPEC GM, CEBALLOS LA, KITRON U & GÜRTLER RE. 2004. Active Dispersal of Natural Populations of Triatoma infestans (Hemiptera: Reduviidae) in Rural Northwestern Argentina. J of Med Ent 41(4): 614-621. the spatial heterogeneity generated by the effects of landscape and vegetation cover may affect the spatial distribution of T. infestans infestations and the risk of house invasion. Scarce vegetation cover around houses can facilitate dispersion between nearby peridomicile because physical and chemical signals from the peridomiciliary area can be sensed in a greater range and they can be used as an orienting cue (Guerensten & Lazzari 2009GUERENSTEN P & LAZZARI C. 2009. How triatomines acquire and make use of information to find blood. Acta Trop 110: 148-158., Catalá 2011CATALÁ SS. 2011. The infra-red (IR) landscape of Triatoma infestans. A hypothesis about the role of IR radiation as a cue for Triatominae dispersal. Infect Genet Evol 11: 1891-1898.).

Multiple factors are determining the chances of peridomestic infestation among which the structural characteristics of the peridomestic structures and its distance to the house, as well as the density of hosts and the history of vector control interventions in the area strongly influence the occurrence of infestation (Gurevitz et al. 2011GUREVITZ JM, CEBALLOS LA, GASPE MS, ALVARADO-OTEGUI JA, ENRÍQUEZ GF, KITRON U & GÜRTLER RE. 2011. Factors affecting infestation by Triatoma infestans in a rural area of the humid Chaco in Argentina: a multi-model inference approach. PLoS Negl Trop Dis 5(10): e1349., Cecere et al. 1997CECERE ME, GURTLER RE, CANALE D & COHEN JE. 1997. El papel del peridomicilio en la eliminación de Triatoma infestans de las comunidades rurales argentinas. Bull Pan Am Health Organ 121: 1-10., Lopez et al. 1999LOPEZ AG, CROCCO L, MORALES G & CATALÁ S. 1999. Feeding frequency and nutritional status of peridomestic populations of Triatoma infestans from Argentina. Acta Trop 73: 275-281.). However, we should also consider the effect of landscape surrounding the house and its potential role as a barrier (in the case of dense and high vegetation) or dispersion facilitator (in the case of low and scarce vegetation).

In order to better understand the factors that modulate the dynamics of dispersion and reinfestation of triatomines at local scales, it is relevant to reinforce the study of the ecological determinants that favor the dispersion of triatomines between habitats, since dispersing triatomines can colonize habitats treated with insecticide, initiating new cycles of colonization and disease transmission (Schofield & Matthews 1985SCHOFIELD CJ & MATTHEWS JN. 1985. Theoretical approach to active dispersal and colonization of houses by Triatoma infestans. Am J Trop Med Hyg 88: 211-222.).

ACKNOWLEDGMENTS

We thank the technicians of the Programa Nacional de Chagas and Programa Provincial de Chagas for the technical and logistical support in the field, Estela Calderón for her invaluable contributions in the work with surveys, Dr. Marcelo Scavuzzo for helping with the image processing and Prof. Carolina Cardozo for the English translation. This work was funded by the National University of Córdoba through the Secretary of Science and Technology and was supported by the Beca Estímulo a las Vocaciones Científicas (EVC-CIN 2015 - Res. P Nº 318/15).

REFERENCES

ABRAHAN L, GORLA DE & CATALÁ SS. 2011. Dispersal of Triatoma infestans and other Triatominae species in the arid Chaco of Argentina - Flying, walking or passive carriage? The importance of walking females. Mem Inst Oswaldo Cruz 106: 232-239.
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CABIDO MR & ZAK MR. 1999. Vegetación del Norte de Córdoba Cabido. Secretaría de Agricultura, Ganadería y Recursos Renovables de Córdoba, p. 55-56.
CABRERA AL. 1976. Regiones Fitogeográficas Argentinas. Enciclopedia Argentina de Agricultura y Jardinería, 2ª Edición, Tomo II, Fascículo I, Acme S.A.C.I., Buenos Aires: Argentina, p. 132-134.
CALCAGNO V. 2013. Glmulti: Model Selection and Multimodel Inference Made Easy. 1.0.7 edn2013: R package. https://cran.r-project.org/web/packages/glmulti/glmulti.pdf
» https://cran.r-project.org/web/packages/glmulti/glmulti.pdf
CANALE DM, CECERE MC, CHUIT R & GÜRTLER RE. 2000. Peridomestic distribution of Triatoma garciabesi and Triatoma guasayana in north-west Argentina. Med Vet Entomol 14: 383-390.
CATALÁ SS. 2011. The infra-red (IR) landscape of Triatoma infestans. A hypothesis about the role of IR radiation as a cue for Triatominae dispersal. Infect Genet Evol 11: 1891-1898.
CECERE MC, VAZQUEZ-PROKOPEC GM, GÜRTLER RE & KITRON U. 2006. Reinfestation sources for Chagas disease vector, Triatoma infestans, Argentina. Emerg Infect Dis J 12: 1096-1102.
CECERE ME, GURTLER RE, CANALE D & COHEN JE. 1997. El papel del peridomicilio en la eliminación de Triatoma infestans de las comunidades rurales argentinas. Bull Pan Am Health Organ 121: 1-10.
CHUIT R, PAULONE I, WISNIVESKY-COLLI CBR, PEREZ AC, SOSA-STANI S & SEGURA EL. 1992. Result of a first step toward community-based surveillance of transmission of Chagas disease with appropriate technology in rural areas. Am J Trop Med Hyg J 46: 444-450.
CROCCO L, NATTERO J, LÓPEZ A, CARDOZO M, SORIA C, ORTIZ V & RODRIGUEZ C. 2019. Factors associated with the presence of triatomines in rural areas of south Argentine Chaco. Rev Soc Bras Med Trop 52: e-20180357.
GORLA DE. 2002. Variables ambientales registradas por sensores remotos como indicadores de la distribución geográfica de Triatoma infestans (Heteroptera: Reduviidae). Ecol Austral 12: 117-127.
GUERENSTEN P & LAZZARI C. 2009. How triatomines acquire and make use of information to find blood. Acta Trop 110: 148-158.
GUREVITZ JM, CEBALLOS LA, GASPE MS, ALVARADO-OTEGUI JA, ENRÍQUEZ GF, KITRON U & GÜRTLER RE. 2011. Factors affecting infestation by Triatoma infestans in a rural area of the humid Chaco in Argentina: a multi-model inference approach. PLoS Negl Trop Dis 5(10): e1349.
GÜRTLER RE. 2009. Sustainability of vector control strategies in the Gran Chaco Region: current challenges and possible approaches. Mem Inst Oswaldo Cruz 04: 52-59.
HOYOS LE, CINGOLANI AM, ZAK MR, VAIERETTI MV, GORLA DE & CABIDO MR. 2013. Deforestation and precipitation patterns in the arid Chaco forests of central Argentina. Appl Veg Sci 16: 230-271.
KARLIN MS, KARLIN UO, COIRINI R O, REATI GJ & ZAPATA RM. 2013. El Chaco Árido. Ed. Encuentro, p. 15-23.
KULLDORFF MA. 1997. A spatial scan statistic. Theory Method 26: 1481-1496.
LENT H & WYGODZINSKY P. 1979. Revision of the Triatominae (Hemiptera, Reduviidae), and their significance as vectors of Chagas disease. Bull Am Mus Nat Hist 163: 123-520.
LOPEZ AG, CROCCO L, MORALES G & CATALÁ S. 1999. Feeding frequency and nutritional status of peridomestic populations of Triatoma infestans from Argentina. Acta Trop 73: 275-281.
MCGARIGAL K, CUSHMAN SA & ENE E. 2012. FRAGSTATS v4: Spatial Pattern Analysis Program for Categorical and Continuous Maps. Computer software program produced by the authors at the University of Massachusetts, Amherst. Available at the following web site: http://www.umass.edu/landeco/research/fragstats/fragstats.html
MCGWIRE K, SEGURA E, SCAVUZZO M, GÓMEZ AA & LAMFRI M. 2006. Spatial pattern of reinfestation by Triatoma infestans in Chancaní, Argentina. J Vector Ecol 31: 17-28.
MORENO M, MORETTI E, BASSO B, FRIAS M, CATALÁ S & GORLA D. 2010. Seroprevalence of Trypanosoma cruzi infection and vector control activities in rural communities of the southern Gran Chaco (Argentina). Acta Trop 113: 257-262.
MORENO ML, HOYOS L, CABIDO M, CATALÁ SS & GORLA DE. 2012. Exploring the association between Trypanosoma cruzi infection in rural communities and environmental changes in the southern Gran Chaco. Mem Inst Oswaldo Cruz 107: 231-237.
OMS - ORGANIZACIÓN MUNDIAL DE LA SALUD. 2007. Reporte sobre la Enfermedad de Chagas. Reporte del grupo de trabajo científico sobre la enfermedad de Chagas. Buenos Aires, Argentina.
PAHO - PAN AMERICAN HEALTH ORGANIZATION. 2012. XIV Reunión de la Comisión Intergubernamental de la Iniciativa de los Países de Centroamérica (IPCA) para la Interrupción de la Transmisión Vectorial, Transfusional y Atención Médica de la Enfermedad de Chagas; Ciudad de Belice, Belice. Available from: https://www.paho.org/hq/dmdocuments/2012/2012-XIV-IPCA-Reunion.pdf
PORCASI X, GORLA DE & SCAVUZZO MC. 2011. A landscape ecology approach for a neglected disease in rural areas of Argentina. Acta Biol Venez 31: 27-32.
RABINOVICH JE. 1972. Vital statistics of Triatominae (Hemiptera: Reduviidae) under laboratory conditions. I. Triatoma infestans Klug. J Med Entomol 9: 351-370.
SCHOFIELD CJ, JANNIN J & SALVATELLA R. 2006. The future of Chagas disease control. Trends Parasitol 12: 583-588.
SCHOFIELD CJ & MATTHEWS JN. 1985. Theoretical approach to active dispersal and colonization of houses by Triatoma infestans. Am J Trop Med Hyg 88: 211-222.
SEGURA EL. 2002. Historia del control de la enfermedad de Chagas en Argentina. En: O controle da doenca de Chagas nos países do Cone Sul da América. História de uma Iniciativa Inernacional, p. 42-109.
SORIA C, CARDOZO M, CANAVOSO LE, CROCCO LB, NATTERO J, ORTIZ VAP, LEYRIA J & RODRIGUEZ CS. 2019. Host influence on the nutritional and reproductive status of Triatoma infestans (Klug) (Hemiptera: Reduviidae) peridomiciliary populations. Rev Soc Entomol Arg 78(2): 1-11.
VAZQUEZ-PROKOPEC GM, CEBALLOS LA, KITRON U & GÜRTLER RE. 2004. Active Dispersal of Natural Populations of Triatoma infestans (Hemiptera: Reduviidae) in Rural Northwestern Argentina. J of Med Ent 41(4): 614-621.
ZUUR AK, IENO EN & SMITH GM. 2007. Data exploration. Analysing Ecological Data. Springer: United States of America, p. 633-648.
ZUUR AK, IENO EN, WALKER NJ, SAVELIEV AA & SMITH GM. 2009. Mixed Effects Models and Extensions in Ecology with R. Springer: United States of America, p. 246-250.

Publication Dates

Publication in this collection
03 Sept 2021
Date of issue
2021

History

Received
30 Sept 2019
Accepted
25 Aug 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ABRAHAN L, GORLA DE & CATALÁ SS. 2011. Dispersal of Triatoma infestans and other Triatominae species in the arid Chaco of Argentina - Flying, walking or passive carriage? The importance of walking females. Mem Inst Oswaldo Cruz 106: 232-239.

[2] BREWER M, GORLA D & GARAY ME. 1983. Caracterización de los estadios ninfales del género Triatoma Laporte, 1833. III Análisis biométrico descriptivo de Triatoma infestans Klug, 1834; Triatoma platensis Neiva, 1913; Triatoma delpontei Romaña y Avalos, 1947 y Triatoma sordida (Stal) 1859 (Hemiptera: Reduviidae). Rev Soc Entomol Arg 42: 219-241.

[3] CABIDO MR & ZAK MR. 1999. Vegetación del Norte de Córdoba Cabido. Secretaría de Agricultura, Ganadería y Recursos Renovables de Córdoba, p. 55-56.

[4] CABRERA AL. 1976. Regiones Fitogeográficas Argentinas. Enciclopedia Argentina de Agricultura y Jardinería, 2ª Edición, Tomo II, Fascículo I, Acme S.A.C.I., Buenos Aires: Argentina, p. 132-134.

[5] CALCAGNO V. 2013. Glmulti: Model Selection and Multimodel Inference Made Easy. 1.0.7 edn2013: R package. https://cran.r-project.org/web/packages/glmulti/glmulti.pdf
» https://cran.r-project.org/web/packages/glmulti/glmulti.pdf

[6] CANALE DM, CECERE MC, CHUIT R & GÜRTLER RE. 2000. Peridomestic distribution of Triatoma garciabesi and Triatoma guasayana in north-west Argentina. Med Vet Entomol 14: 383-390.

[7] CATALÁ SS. 2011. The infra-red (IR) landscape of Triatoma infestans. A hypothesis about the role of IR radiation as a cue for Triatominae dispersal. Infect Genet Evol 11: 1891-1898.

[8] CECERE MC, VAZQUEZ-PROKOPEC GM, GÜRTLER RE & KITRON U. 2006. Reinfestation sources for Chagas disease vector, Triatoma infestans, Argentina. Emerg Infect Dis J 12: 1096-1102.

[9] CECERE ME, GURTLER RE, CANALE D & COHEN JE. 1997. El papel del peridomicilio en la eliminación de Triatoma infestans de las comunidades rurales argentinas. Bull Pan Am Health Organ 121: 1-10.

[10] CHUIT R, PAULONE I, WISNIVESKY-COLLI CBR, PEREZ AC, SOSA-STANI S & SEGURA EL. 1992. Result of a first step toward community-based surveillance of transmission of Chagas disease with appropriate technology in rural areas. Am J Trop Med Hyg J 46: 444-450.

[11] CROCCO L, NATTERO J, LÓPEZ A, CARDOZO M, SORIA C, ORTIZ V & RODRIGUEZ C. 2019. Factors associated with the presence of triatomines in rural areas of south Argentine Chaco. Rev Soc Bras Med Trop 52: e-20180357.

[12] GORLA DE. 2002. Variables ambientales registradas por sensores remotos como indicadores de la distribución geográfica de Triatoma infestans (Heteroptera: Reduviidae). Ecol Austral 12: 117-127.

[13] GUERENSTEN P & LAZZARI C. 2009. How triatomines acquire and make use of information to find blood. Acta Trop 110: 148-158.

[14] GUREVITZ JM, CEBALLOS LA, GASPE MS, ALVARADO-OTEGUI JA, ENRÍQUEZ GF, KITRON U & GÜRTLER RE. 2011. Factors affecting infestation by Triatoma infestans in a rural area of the humid Chaco in Argentina: a multi-model inference approach. PLoS Negl Trop Dis 5(10): e1349.

[15] GÜRTLER RE. 2009. Sustainability of vector control strategies in the Gran Chaco Region: current challenges and possible approaches. Mem Inst Oswaldo Cruz 04: 52-59.

[16] HOYOS LE, CINGOLANI AM, ZAK MR, VAIERETTI MV, GORLA DE & CABIDO MR. 2013. Deforestation and precipitation patterns in the arid Chaco forests of central Argentina. Appl Veg Sci 16: 230-271.

[17] KARLIN MS, KARLIN UO, COIRINI R O, REATI GJ & ZAPATA RM. 2013. El Chaco Árido. Ed. Encuentro, p. 15-23.

[18] KULLDORFF MA. 1997. A spatial scan statistic. Theory Method 26: 1481-1496.

[19] LENT H & WYGODZINSKY P. 1979. Revision of the Triatominae (Hemiptera, Reduviidae), and their significance as vectors of Chagas disease. Bull Am Mus Nat Hist 163: 123-520.

[20] LOPEZ AG, CROCCO L, MORALES G & CATALÁ S. 1999. Feeding frequency and nutritional status of peridomestic populations of Triatoma infestans from Argentina. Acta Trop 73: 275-281.

[21] MCGARIGAL K, CUSHMAN SA & ENE E. 2012. FRAGSTATS v4: Spatial Pattern Analysis Program for Categorical and Continuous Maps. Computer software program produced by the authors at the University of Massachusetts, Amherst. Available at the following web site: http://www.umass.edu/landeco/research/fragstats/fragstats.html

[22] MCGWIRE K, SEGURA E, SCAVUZZO M, GÓMEZ AA & LAMFRI M. 2006. Spatial pattern of reinfestation by Triatoma infestans in Chancaní, Argentina. J Vector Ecol 31: 17-28.

[23] MORENO M, MORETTI E, BASSO B, FRIAS M, CATALÁ S & GORLA D. 2010. Seroprevalence of Trypanosoma cruzi infection and vector control activities in rural communities of the southern Gran Chaco (Argentina). Acta Trop 113: 257-262.

[24] MORENO ML, HOYOS L, CABIDO M, CATALÁ SS & GORLA DE. 2012. Exploring the association between Trypanosoma cruzi infection in rural communities and environmental changes in the southern Gran Chaco. Mem Inst Oswaldo Cruz 107: 231-237.

[25] OMS - ORGANIZACIÓN MUNDIAL DE LA SALUD. 2007. Reporte sobre la Enfermedad de Chagas. Reporte del grupo de trabajo científico sobre la enfermedad de Chagas. Buenos Aires, Argentina.

[26] PAHO - PAN AMERICAN HEALTH ORGANIZATION. 2012. XIV Reunión de la Comisión Intergubernamental de la Iniciativa de los Países de Centroamérica (IPCA) para la Interrupción de la Transmisión Vectorial, Transfusional y Atención Médica de la Enfermedad de Chagas; Ciudad de Belice, Belice. Available from: https://www.paho.org/hq/dmdocuments/2012/2012-XIV-IPCA-Reunion.pdf

[27] PORCASI X, GORLA DE & SCAVUZZO MC. 2011. A landscape ecology approach for a neglected disease in rural areas of Argentina. Acta Biol Venez 31: 27-32.

[28] RABINOVICH JE. 1972. Vital statistics of Triatominae (Hemiptera: Reduviidae) under laboratory conditions. I. Triatoma infestans Klug. J Med Entomol 9: 351-370.

[29] SCHOFIELD CJ, JANNIN J & SALVATELLA R. 2006. The future of Chagas disease control. Trends Parasitol 12: 583-588.

[30] SCHOFIELD CJ & MATTHEWS JN. 1985. Theoretical approach to active dispersal and colonization of houses by Triatoma infestans. Am J Trop Med Hyg 88: 211-222.

[31] SEGURA EL. 2002. Historia del control de la enfermedad de Chagas en Argentina. En: O controle da doenca de Chagas nos países do Cone Sul da América. História de uma Iniciativa Inernacional, p. 42-109.

[32] SORIA C, CARDOZO M, CANAVOSO LE, CROCCO LB, NATTERO J, ORTIZ VAP, LEYRIA J & RODRIGUEZ CS. 2019. Host influence on the nutritional and reproductive status of Triatoma infestans (Klug) (Hemiptera: Reduviidae) peridomiciliary populations. Rev Soc Entomol Arg 78(2): 1-11.

[33] VAZQUEZ-PROKOPEC GM, CEBALLOS LA, KITRON U & GÜRTLER RE. 2004. Active Dispersal of Natural Populations of Triatoma infestans (Hemiptera: Reduviidae) in Rural Northwestern Argentina. J of Med Ent 41(4): 614-621.

[34] ZUUR AK, IENO EN & SMITH GM. 2007. Data exploration. Analysing Ecological Data. Springer: United States of America, p. 633-648.

[35] ZUUR AK, IENO EN, WALKER NJ, SAVELIEV AA & SMITH GM. 2009. Mixed Effects Models and Extensions in Ecology with R. Springer: United States of America, p. 246-250.

Rural community	Evaluated houses	Infested domicile	Infested peridomicile	Triatomines
Rural community	Evaluated houses	Infested domicile	Infested peridomicile	Nymphs	Adults
Puesto Torrado	5	0	2	38	1
Villa Lujan	2	0	0	0	0
Palo Parado	15	1	7	74	24
El Simbolar	26	0	9	71	22
La Concepción	3	0	2	4	44
Villa de Soto	15	0	9	264	91

Model	Model structure	AICc	∆AICc	AICcWt
m 1	Y (HD)	91.17	0.00	0.23
m 12	Y (HD + Open Shrubland)	92.12	0.95	0.14
m 7	Y (HD + IPD)	92.19	1.02	0.14
m 13	Y (IPD + HD + Open Shrubland)	93.20	2.03	0.08
m 4	Y (Open Shrubland)	93.30	2.14	0.08
m 3	Y (Cultural Land)	93.91	2.75	0.06
m 6	Y (Open Forest)	94.30	3.13	0.05
m 14	Y (IPD + HD + Closed Shrubland)	94.45	3.29	0.04
m 2	Y (IPD)	94.57	3.40	0.04
m 5	Y (Closed Shrubland)	94.62	3.45	0.04
m 10	Y Open Shrubland + Open Forest)	94.63	3.47	0.04
m 11	Y (IPD + Open Shrubland)	95.39	4.22	0.03
m 9	Y (Open Shrubland + Closed Shrubland)	95.50	4.33	0.03
m 8	Y (Open Shrubland + Closed Shrubland + Open Forest)	96.66	5.49	0.01
Null Model	Y (1)	99.02	7.85	0.00

Brasil

Brasil

Modelling the effect of density vegetation coverage and the occurrence of peridomestic infestation by Triatoma infestans in rural houses of northwest of Córdoba, Argentina

Abstract

INTRODUCTION

MATERIALS AND METHODS

Study area

Entomological data

Estimation of vegetation cover and spatial variables

Statistical analysis

RESULTS

Entomological data

Estimation of vegetation cover and spatial variables

Spatial analysis and multi-model inference

DISCUSSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History